1 during each round of cell division, the successful partitioning of chromosomes is carried out by the mitotic spindle, a chemomechanical machine that is comprised of microtubules, molecular motors, and associated regulatory proteins. Due to its central role in cell biology and because it is a target for antimitotic cancer therapies, there is a large research effort underway to understand mechanisms underlying spindle morphogenesis and maintenance. Experiments in cells have defined a number of molecular motors and other proteins that are involved in mitosis. However, because of the large number of molecules involved and the built-in functional redundancy employed to prevent chromosome missegregation, there are many unresolved questions regarding the precise molecular interactions and physical mechanisms driving mitosis. In particular, there is a gap between single-molecule investigations on isolated proteins and the behavior observed in the complex environment of the cell. The goal of this project is to assemble microtubules into artificial mitotic spindles in vitro, and to apply this novel experimental tool to study the performance of specific motor and microtubule binding proteins in a geometry resembling that found in dividing cells. The artificial spindles will be assembled using microfabricated chambers, AC electric fields and surface patterned motor proteins, and the resulting structures will be characterized using fluorescence microscopy. Specific experiments will be carried out to test the sufficiency of current models of spindle morphogenesis and maintenance. The first two experiments will test the ability of motors to center themselves on the artificial spindle and reorganize the spindle microtubules. The third experiment will test the ability of a C-terminal kinesin motor to focus the microtubule ends into the tight clusters found in cells. By recreating the complex intracellular architecture of the mitotic spindle in vitro, this approach will uncover the nanoscale dynamic interactions of motor proteins and microtubules underlying mitosis in a way that is not possible using current single-molecule measurements or measurements in intact cells. ? ? Relevance: The goal of this work is to develop a new approach to studying the molecular mechanisms underlying cell division in animal cells. Because cancer results from uncontrolled cell division, this work is an important step towards developing novel anti-tumor therapies. ? ? ?

Agency
National Institute of Health (NIH)
Institute
National Institute of General Medical Sciences (NIGMS)
Type
Exploratory/Developmental Grants (R21)
Project #
1R21GM083297-01
Application #
7363764
Study Section
Special Emphasis Panel (ZRG1-BST-M (51))
Program Officer
Lewis, Catherine D
Project Start
2008-06-01
Project End
2010-05-31
Budget Start
2008-06-01
Budget End
2009-05-31
Support Year
1
Fiscal Year
2008
Total Cost
$213,651
Indirect Cost
Name
Pennsylvania State University
Department
Biomedical Engineering
Type
Schools of Engineering
DUNS #
003403953
City
University Park
State
PA
Country
United States
Zip Code
16802
Hay, Charles E; Gonzalez 3rd, Guillermo A; Ewing, Laura E et al. (2018) Development and testing of AAV-delivered single-chain variable fragments for the treatment of methamphetamine abuse. PLoS One 13:e0200060
Uppalapati, Maruti; Huang, Ying-Ming; Aravamuthan, Vidhya et al. (2011) ""Artificial mitotic spindle"" generated by dielectrophoresis and protein micropatterning supports bidirectional transport of kinesin-coated beads. Integr Biol (Camb) 3:57-64
Malcos, Jennelle L; Hancock, William O (2011) Engineering tubulin: microtubule functionalization approaches for nanoscale device applications. Appl Microbiol Biotechnol 90:1-10